boost/interprocess/allocators/detail/node_pool.hpp
//////////////////////////////////////////////////////////////////////////////
//
// (C) Copyright Ion Gaztanaga 2005-2008. Distributed under the Boost
// Software License, Version 1.0. (See accompanying file
// LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
//
// See http://www.boost.org/libs/interprocess for documentation.
//
//////////////////////////////////////////////////////////////////////////////
#ifndef BOOST_INTERPROCESS_DETAIL_NODE_POOL_HPP
#define BOOST_INTERPROCESS_DETAIL_NODE_POOL_HPP
#if (defined _MSC_VER) && (_MSC_VER >= 1200)
# pragma once
#endif
#include <boost/interprocess/detail/config_begin.hpp>
#include <boost/interprocess/detail/workaround.hpp>
#include <boost/interprocess/sync/interprocess_mutex.hpp>
#include <boost/interprocess/detail/utilities.hpp>
#include <boost/interprocess/exceptions.hpp>
#include <boost/intrusive/slist.hpp>
#include <boost/math/common_factor_ct.hpp>
#include <boost/interprocess/detail/math_functions.hpp>
#include <boost/interprocess/detail/type_traits.hpp>
#include <boost/interprocess/allocators/detail/node_tools.hpp>
#include <boost/interprocess/allocators/detail/allocator_common.hpp>
#include <cstddef>
#include <functional>
#include <algorithm>
#include <cassert>
//!\file
//!Describes the real adaptive pool shared by many Interprocess adaptive pool allocators
namespace boost {
namespace interprocess {
namespace detail {
template<class SegmentManagerBase>
class private_node_pool_impl
{
//Non-copyable
private_node_pool_impl();
private_node_pool_impl(const private_node_pool_impl &);
private_node_pool_impl &operator=(const private_node_pool_impl &);
//A node object will hold node_t when it's not allocated
public:
typedef typename SegmentManagerBase::void_pointer void_pointer;
typedef typename node_slist<void_pointer>::slist_hook_t slist_hook_t;
typedef typename node_slist<void_pointer>::node_t node_t;
typedef typename node_slist<void_pointer>::node_slist_t free_nodes_t;
typedef typename SegmentManagerBase::multiallocation_iterator multiallocation_iterator;
typedef typename SegmentManagerBase::multiallocation_chain multiallocation_chain;
private:
typedef typename bi::make_slist
< node_t, bi::base_hook<slist_hook_t>
, bi::linear<true>
, bi::constant_time_size<false> >::type blockslist_t;
public:
//!Segment manager typedef
typedef SegmentManagerBase segment_manager_base_type;
//!Constructor from a segment manager. Never throws
private_node_pool_impl(segment_manager_base_type *segment_mngr_base, std::size_t node_size, std::size_t nodes_per_block)
: m_nodes_per_block(nodes_per_block)
, m_real_node_size(detail::lcm(node_size, std::size_t(alignment_of<node_t>::value)))
//General purpose allocator
, mp_segment_mngr_base(segment_mngr_base)
, m_blocklist()
, m_freelist()
//Debug node count
, m_allocated(0)
{}
//!Destructor. Deallocates all allocated blocks. Never throws
~private_node_pool_impl()
{ this->purge_blocks(); }
std::size_t get_real_num_node() const
{ return m_nodes_per_block; }
//!Returns the segment manager. Never throws
segment_manager_base_type* get_segment_manager_base()const
{ return detail::get_pointer(mp_segment_mngr_base); }
//!Allocates array of count elements. Can throw boost::interprocess::bad_alloc
void *allocate_node()
{
//If there are no free nodes we allocate a new block
if (m_freelist.empty())
priv_alloc_block();
//We take the first free node
node_t *n = &m_freelist.front();
m_freelist.pop_front();
++m_allocated;
return n;
}
//!Deallocates an array pointed by ptr. Never throws
void deallocate_node(void *ptr)
{
//We put the node at the beginning of the free node list
node_t * to_deallocate = static_cast<node_t*>(ptr);
m_freelist.push_front(*to_deallocate);
assert(m_allocated>0);
--m_allocated;
}
//!Allocates a singly linked list of n nodes ending in null pointer and pushes them in the chain.
//!can throw boost::interprocess::bad_alloc
void allocate_nodes(multiallocation_chain &nodes, const std::size_t n)
{
std::size_t i = 0;
try{
for(; i < n; ++i){
nodes.push_front(this->allocate_node());
}
}
catch(...){
this->deallocate_nodes(nodes, i);
throw;
}
}
//!Allocates a singly linked list of n nodes ending in null pointer
//!can throw boost::interprocess::bad_alloc
multiallocation_iterator allocate_nodes(const std::size_t n)
{
multiallocation_chain nodes;
std::size_t i = 0;
try{
for(; i < n; ++i){
nodes.push_front(this->allocate_node());
}
}
catch(...){
this->deallocate_nodes(nodes, i);
throw;
}
return nodes.get_it();
}
//!Deallocates a linked list of nodes. Never throws
void deallocate_nodes(multiallocation_chain &nodes)
{
this->deallocate_nodes(nodes.get_it());
nodes.reset();
}
//!Deallocates the first n nodes of a linked list of nodes. Never throws
void deallocate_nodes(multiallocation_chain &nodes, std::size_t num)
{
assert(nodes.size() >= num);
for(std::size_t i = 0; i < num; ++i){
deallocate_node(nodes.pop_front());
}
}
//!Deallocates the nodes pointed by the multiallocation iterator. Never throws
void deallocate_nodes(multiallocation_iterator it)
{
multiallocation_iterator itend;
while(it != itend){
void *addr = &*it;
++it;
deallocate_node(addr);
}
}
//!Deallocates all the free blocks of memory. Never throws
void deallocate_free_blocks()
{
typedef typename free_nodes_t::iterator nodelist_iterator;
typename blockslist_t::iterator bit(m_blocklist.before_begin()),
it(m_blocklist.begin()),
itend(m_blocklist.end());
free_nodes_t backup_list;
nodelist_iterator backup_list_last = backup_list.before_begin();
//Execute the algorithm and get an iterator to the last value
std::size_t blocksize = detail::get_rounded_size
(m_real_node_size*m_nodes_per_block, alignment_of<node_t>::value);
while(it != itend){
//Collect all the nodes from the block pointed by it
//and push them in the list
free_nodes_t free_nodes;
nodelist_iterator last_it = free_nodes.before_begin();
const void *addr = get_block_from_hook(&*it, blocksize);
m_freelist.remove_and_dispose_if
(is_between(addr, blocksize), push_in_list(free_nodes, last_it));
//If the number of nodes is equal to m_nodes_per_block
//this means that the block can be deallocated
if(free_nodes.size() == m_nodes_per_block){
//Unlink the nodes
free_nodes.clear();
it = m_blocklist.erase_after(bit);
mp_segment_mngr_base->deallocate((void*)addr);
}
//Otherwise, insert them in the backup list, since the
//next "remove_if" does not need to check them again.
else{
//Assign the iterator to the last value if necessary
if(backup_list.empty() && !m_freelist.empty()){
backup_list_last = last_it;
}
//Transfer nodes. This is constant time.
backup_list.splice_after
( backup_list.before_begin()
, free_nodes
, free_nodes.before_begin()
, last_it
, free_nodes.size());
bit = it;
++it;
}
}
//We should have removed all the nodes from the free list
assert(m_freelist.empty());
//Now pass all the node to the free list again
m_freelist.splice_after
( m_freelist.before_begin()
, backup_list
, backup_list.before_begin()
, backup_list_last
, backup_list.size());
}
std::size_t num_free_nodes()
{ return m_freelist.size(); }
//!Deallocates all used memory. Precondition: all nodes allocated from this pool should
//!already be deallocated. Otherwise, undefined behaviour. Never throws
void purge_blocks()
{
//check for memory leaks
assert(m_allocated==0);
std::size_t blocksize = detail::get_rounded_size
(m_real_node_size*m_nodes_per_block, alignment_of<node_t>::value);
typename blockslist_t::iterator
it(m_blocklist.begin()), itend(m_blocklist.end()), aux;
//We iterate though the NodeBlock list to free the memory
while(!m_blocklist.empty()){
void *addr = get_block_from_hook(&m_blocklist.front(), blocksize);
m_blocklist.pop_front();
mp_segment_mngr_base->deallocate((void*)addr);
}
//Just clear free node list
m_freelist.clear();
}
void swap(private_node_pool_impl &other)
{
std::swap(mp_segment_mngr_base, other.mp_segment_mngr_base);
m_blocklist.swap(other.m_blocklist);
m_freelist.swap(other.m_freelist);
std::swap(m_allocated, other.m_allocated);
}
private:
struct push_in_list
{
push_in_list(free_nodes_t &l, typename free_nodes_t::iterator &it)
: slist_(l), last_it_(it)
{}
void operator()(typename free_nodes_t::pointer p) const
{
slist_.push_front(*p);
if(slist_.size() == 1){ //Cache last element
++last_it_ = slist_.begin();
}
}
private:
free_nodes_t &slist_;
typename free_nodes_t::iterator &last_it_;
};
struct is_between
: std::unary_function<typename free_nodes_t::value_type, bool>
{
is_between(const void *addr, std::size_t size)
: beg_(static_cast<const char *>(addr)), end_(beg_+size)
{}
bool operator()(typename free_nodes_t::const_reference v) const
{
return (beg_ <= reinterpret_cast<const char *>(&v) &&
end_ > reinterpret_cast<const char *>(&v));
}
private:
const char * beg_;
const char * end_;
};
//!Allocates a block of nodes. Can throw boost::interprocess::bad_alloc
void priv_alloc_block()
{
//We allocate a new NodeBlock and put it as first
//element in the free Node list
std::size_t blocksize =
detail::get_rounded_size(m_real_node_size*m_nodes_per_block, alignment_of<node_t>::value);
char *pNode = reinterpret_cast<char*>
(mp_segment_mngr_base->allocate(blocksize + sizeof(node_t)));
if(!pNode) throw bad_alloc();
char *pBlock = pNode;
m_blocklist.push_front(get_block_hook(pBlock, blocksize));
//We initialize all Nodes in Node Block to insert
//them in the free Node list
for(std::size_t i = 0; i < m_nodes_per_block; ++i, pNode += m_real_node_size){
m_freelist.push_front(*new (pNode) node_t);
}
}
//!Deprecated, use deallocate_free_blocks
void deallocate_free_chunks()
{ this->deallocate_free_blocks(); }
//!Deprecated, use purge_blocks
void purge_chunks()
{ this->purge_blocks(); }
private:
//!Returns a reference to the block hook placed in the end of the block
static inline node_t & get_block_hook (void *block, std::size_t blocksize)
{
return *reinterpret_cast<node_t*>(reinterpret_cast<char*>(block) + blocksize);
}
//!Returns the starting address of the block reference to the block hook placed in the end of the block
inline void *get_block_from_hook (node_t *hook, std::size_t blocksize)
{
return (reinterpret_cast<char*>(hook) - blocksize);
}
private:
typedef typename pointer_to_other
<void_pointer, segment_manager_base_type>::type segment_mngr_base_ptr_t;
const std::size_t m_nodes_per_block;
const std::size_t m_real_node_size;
segment_mngr_base_ptr_t mp_segment_mngr_base; //Segment manager
blockslist_t m_blocklist; //Intrusive container of blocks
free_nodes_t m_freelist; //Intrusive container of free nods
std::size_t m_allocated; //Used nodes for debugging
};
//!Pooled shared memory allocator using single segregated storage. Includes
//!a reference count but the class does not delete itself, this is
//!responsibility of user classes. Node size (NodeSize) and the number of
//!nodes allocated per block (NodesPerBlock) are known at compile time
template< class SegmentManager, std::size_t NodeSize, std::size_t NodesPerBlock >
class private_node_pool
//Inherit from the implementation to avoid template bloat
: public private_node_pool_impl<typename SegmentManager::segment_manager_base_type>
{
typedef private_node_pool_impl<typename SegmentManager::segment_manager_base_type> base_t;
//Non-copyable
private_node_pool();
private_node_pool(const private_node_pool &);
private_node_pool &operator=(const private_node_pool &);
public:
typedef SegmentManager segment_manager;
static const std::size_t nodes_per_block = NodesPerBlock;
//Deprecated, use nodes_per_block
static const std::size_t nodes_per_chunk = NodesPerBlock;
//!Constructor from a segment manager. Never throws
private_node_pool(segment_manager *segment_mngr)
: base_t(segment_mngr, NodeSize, NodesPerBlock)
{}
//!Returns the segment manager. Never throws
segment_manager* get_segment_manager() const
{ return static_cast<segment_manager*>(base_t::get_segment_manager_base()); }
};
//!Pooled shared memory allocator using single segregated storage. Includes
//!a reference count but the class does not delete itself, this is
//!responsibility of user classes. Node size (NodeSize) and the number of
//!nodes allocated per block (NodesPerBlock) are known at compile time
//!Pooled shared memory allocator using adaptive pool. Includes
//!a reference count but the class does not delete itself, this is
//!responsibility of user classes. Node size (NodeSize) and the number of
//!nodes allocated per block (NodesPerBlock) are known at compile time
template< class SegmentManager
, std::size_t NodeSize
, std::size_t NodesPerBlock
>
class shared_node_pool
: public detail::shared_pool_impl
< private_node_pool
<SegmentManager, NodeSize, NodesPerBlock>
>
{
typedef detail::shared_pool_impl
< private_node_pool
<SegmentManager, NodeSize, NodesPerBlock>
> base_t;
public:
shared_node_pool(SegmentManager *segment_mgnr)
: base_t(segment_mgnr)
{}
};
} //namespace detail {
} //namespace interprocess {
} //namespace boost {
#include <boost/interprocess/detail/config_end.hpp>
#endif //#ifndef BOOST_INTERPROCESS_DETAIL_NODE_POOL_HPP